/***************************************************************************
 *   Copyright (c) 2004 Werner Mayer <wmayer[at]users.sourceforge.net>     *
 *                                                                         *
 *   This file is part of the FreeCAD CAx development system.              *
 *                                                                         *
 *   This library is free software; you can redistribute it and/or         *
 *   modify it under the terms of the GNU Library General Public           *
 *   License as published by the Free Software Foundation; either          *
 *   version 2 of the License, or (at your option) any later version.      *
 *                                                                         *
 *   This library  is distributed in the hope that it will be useful,      *
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of        *
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 *   GNU Library General Public License for more details.                  *
 *                                                                         *
 *   You should have received a copy of the GNU Library General Public     *
 *   License along with this library; see the file COPYING.LIB. If not,    *
 *   write to the Free Software Foundation, Inc., 59 Temple Place,         *
 *   Suite 330, Boston, MA  02111-1307, USA                                *
 *                                                                         *
 ***************************************************************************/

#include "PreCompiled.h"
#ifndef _PreComp_
#include <cstdlib>
#include <QAction>
#include <QMenu>

#include <Inventor/SbBox2s.h>
#include <Inventor/SbLine.h>
#include <Inventor/SbPlane.h>
#include <Inventor/SoPickedPoint.h>
#include <Inventor/actions/SoToVRML2Action.h>
#include <Inventor/details/SoFaceDetail.h>
#include <Inventor/events/SoMouseButtonEvent.h>
#include <Inventor/nodes/SoBaseColor.h>
#include <Inventor/nodes/SoCoordinate3.h>
#include <Inventor/nodes/SoDrawStyle.h>
#include <Inventor/nodes/SoLightModel.h>
#include <Inventor/nodes/SoIndexedFaceSet.h>
#include <Inventor/nodes/SoIndexedLineSet.h>
#include <Inventor/nodes/SoMaterial.h>
#include <Inventor/nodes/SoMaterialBinding.h>
#include <Inventor/nodes/SoOrthographicCamera.h>
#include <Inventor/nodes/SoPerspectiveCamera.h>
#include <Inventor/nodes/SoPolygonOffset.h>
#include <Inventor/nodes/SoShapeHints.h>
#include <Inventor/nodes/SoSeparator.h>
#include <Inventor/nodes/SoTransform.h>
#include <Inventor/VRMLnodes/SoVRMLGroup.h>
#endif

#include <QFuture>
#include <QFutureWatcher>
#include <QtConcurrentMap>

#include <App/Document.h>
#include <Base/Console.h>
#include <Base/Exception.h>
#include <Base/Sequencer.h>
#include <Base/Stream.h>
#include <Base/Tools.h>
#include <Base/ViewProj.h>
#include <Gui/ActionFunction.h>
#include <Gui/Application.h>
#include <Gui/BitmapFactory.h>
#include <Gui/Command.h>
#include <Gui/Document.h>
#include <Gui/Flag.h>
#include <Gui/Selection.h>
#include <Gui/SoFCDB.h>
#include <Gui/SoFCOffscreenRenderer.h>
#include <Gui/SoFCSelection.h>
#include <Gui/SoFCSelectionAction.h>
#include <Gui/Utilities.h>
#include <Gui/View3DInventorViewer.h>
#include <Gui/WaitCursor.h>
#include <Gui/Window.h>
#include <Mod/Mesh/App/Core/Algorithm.h>
#include <Mod/Mesh/App/Core/Grid.h>
#include <Mod/Mesh/App/Core/Iterator.h>
#include <Mod/Mesh/App/Core/MeshIO.h>
#include <Mod/Mesh/App/Core/Triangulation.h>
#include <Mod/Mesh/App/Core/Trim.h>
#include <Mod/Mesh/App/Core/Visitor.h>
#include <Mod/Mesh/App/MeshFeature.h>
#include <Mod/Mesh/Gui/ViewProviderMeshPy.h>
#include <zipios++/gzipoutputstream.h>

#include "SoFCIndexedFaceSet.h"
#include "SoFCMeshObject.h"
#include "ViewProvider.h"


using namespace MeshGui;
namespace sp = std::placeholders;

using Mesh::Feature;
using MeshCore::MeshFacet;
using MeshCore::MeshFacetIterator;
using MeshCore::MeshGeomFacet;
using MeshCore::MeshKernel;
using MeshCore::MeshPointIterator;

void ViewProviderMeshBuilder::buildNodes(const App::Property* prop,
                                         std::vector<SoNode*>& nodes) const
{
    SoCoordinate3* pcPointsCoord = nullptr;
    SoIndexedFaceSet* pcFaces = nullptr;

    if (nodes.empty()) {
        pcPointsCoord = new SoCoordinate3();
        nodes.push_back(pcPointsCoord);
        pcFaces = new SoIndexedFaceSet();
        nodes.push_back(pcFaces);
    }
    else if (nodes.size() == 2) {
        if (nodes[0]->getTypeId() == SoCoordinate3::getClassTypeId()) {
            pcPointsCoord = static_cast<SoCoordinate3*>(nodes[0]);
        }
        if (nodes[1]->getTypeId() == SoIndexedFaceSet::getClassTypeId()) {
            pcFaces = static_cast<SoIndexedFaceSet*>(nodes[1]);
        }
    }

    if (pcPointsCoord && pcFaces) {
        createMesh(prop, pcPointsCoord, pcFaces);
    }
}

void ViewProviderMeshBuilder::createMesh(const App::Property* prop,
                                         SoCoordinate3* coords,
                                         SoIndexedFaceSet* faces) const
{
    const Mesh::PropertyMeshKernel* mesh = static_cast<const Mesh::PropertyMeshKernel*>(prop);
    const MeshCore::MeshKernel& rcMesh = mesh->getValue().getKernel();
    createMesh(rcMesh, coords, faces);
}

void ViewProviderMeshBuilder::createMesh(const MeshCore::MeshKernel& kernel,
                                         SoCoordinate3* coords,
                                         SoIndexedFaceSet* faces) const
{

    // set the point coordinates
    const MeshCore::MeshPointArray& cP = kernel.GetPoints();
    coords->point.setNum(kernel.CountPoints());
    SbVec3f* verts = coords->point.startEditing();
    int i = 0;
    for (MeshCore::MeshPointArray::_TConstIterator it = cP.begin(); it != cP.end(); ++it, i++) {
        verts[i].setValue(it->x, it->y, it->z);
    }
    coords->point.finishEditing();

    // set the face indices
    int j = 0;
    const MeshCore::MeshFacetArray& cF = kernel.GetFacets();
    faces->coordIndex.setNum(4 * kernel.CountFacets());
    int32_t* indices = faces->coordIndex.startEditing();
    for (MeshCore::MeshFacetArray::_TConstIterator it = cF.begin(); it != cF.end(); ++it, j++) {
        for (int i = 0; i < 3; i++) {
            indices[4 * j + i] = it->_aulPoints[i];
        }
        indices[4 * j + 3] = SO_END_FACE_INDEX;
    }
    faces->coordIndex.finishEditing();
}

PROPERTY_SOURCE(MeshGui::ViewProviderExport, Gui::ViewProviderDocumentObject)

ViewProviderExport::ViewProviderExport() = default;

ViewProviderExport::~ViewProviderExport() = default;

std::vector<std::string> ViewProviderExport::getDisplayModes() const
{
    std::vector<std::string> mode;
    mode.emplace_back("");
    return mode;
}

const char* ViewProviderExport::getDefaultDisplayMode() const
{
    return "";
}

QIcon ViewProviderExport::getIcon() const
{
    // clang-format off
    const char * Mesh_Feature_xpm[] = {
        "22 22 6 1",
        ". c None",
        "# c #000000",
        "c c #ffff00",
        "a c #808080",
        "b c #c0c0c0",
        "f c #008000",
        ".............##.......",
        ".............###......",
        ".............#f##.....",
        ".#....####...#ff##....",
        ".##.##....#..#fff##...",
        ".###.........#ffff##..",
        ".####........#fffff##.",
        ".#####.......#ffffff##",
        ".............#########",
        ".####.................",
        "#abab##########.......",
        "#babababababab#.......",
        "#ababababababa#.......",
        "#babab################",
        "#abab##cccccccccccc##.",
        "#bab##cccccccccccc##..",
        "#ab##cccccccccccc##...",
        "#b##cccccccccccc##....",
        "###cccccccccccc##.....",
        "##cccccccccccc##......",
        "###############.......",
        "......................"};
    QPixmap px(Mesh_Feature_xpm);
    return px;
    // clang-format on
}

// ------------------------------------------------------

App::PropertyFloatConstraint::Constraints ViewProviderMesh::floatRange = {1.0F, 64.0F, 1.0F};
App::PropertyFloatConstraint::Constraints ViewProviderMesh::angleRange = {0.0F, 180.0F, 1.0F};
App::PropertyIntegerConstraint::Constraints ViewProviderMesh::intPercent = {0, 100, 5};
const char* ViewProviderMesh::LightingEnums[] = {"One side", "Two side", nullptr};

PROPERTY_SOURCE(MeshGui::ViewProviderMesh, Gui::ViewProviderGeometryObject)

ViewProviderMesh::ViewProviderMesh()
    : highlightMode {HighlighMode::None}
{
    // NOLINTBEGIN
    static const char* osgroup = "Object Style";

    ADD_PROPERTY_TYPE(LineTransparency, (0), osgroup, App::Prop_None, "Set line transparency.");
    LineTransparency.setConstraints(&intPercent);
    ADD_PROPERTY_TYPE(LineWidth, (1.0f), osgroup, App::Prop_None, "Set line width.");
    LineWidth.setConstraints(&floatRange);
    ADD_PROPERTY_TYPE(PointSize, (2.0f), osgroup, App::Prop_None, "Set point size.");
    PointSize.setConstraints(&floatRange);
    ADD_PROPERTY_TYPE(CreaseAngle, (0.0f), osgroup, App::Prop_None, "Set crease angle.");
    CreaseAngle.setConstraints(&angleRange);
    ADD_PROPERTY_TYPE(OpenEdges, (false), osgroup, App::Prop_None, "Set open edges.");
    ADD_PROPERTY_TYPE(Coloring, (false), osgroup, App::Prop_None, "Set coloring.");
    ADD_PROPERTY_TYPE(Lighting,
                      (1),
                      osgroup,
                      App::Prop_None,
                      "Set if the illumination comes from two sides\n or one side in the 3D view.");
    Lighting.setEnums(LightingEnums);
    ADD_PROPERTY_TYPE(LineColor, (0, 0, 0), osgroup, App::Prop_None, "Set line color.");

    // Create the selection node
    pcHighlight = Gui::ViewProviderBuilder::createSelection();
    pcHighlight->ref();
    if (pcHighlight->selectionMode.getValue() == Gui::SoFCSelection::SEL_OFF) {
        Selectable.setValue(false);
    }

    pcShapeGroup = new SoGroup();
    pcShapeGroup->ref();
    pcHighlight->addChild(pcShapeGroup);

    pOpenColor = new SoBaseColor();
    setOpenEdgeColorFrom(ShapeColor.getValue());
    pOpenColor->ref();

    pcLineStyle = new SoDrawStyle();
    pcLineStyle->ref();
    pcLineStyle->style = SoDrawStyle::LINES;
    pcLineStyle->lineWidth = LineWidth.getValue();

    pcPointStyle = new SoDrawStyle();
    pcPointStyle->ref();
    pcPointStyle->style = SoDrawStyle::POINTS;
    pcPointStyle->pointSize = PointSize.getValue();

    pShapeHints = new SoShapeHints;
    pShapeHints->shapeType = SoShapeHints::UNKNOWN_SHAPE_TYPE;
    pShapeHints->ref();

    pcMatBinding = new SoMaterialBinding;
    pcMatBinding->value = SoMaterialBinding::OVERALL;
    pcMatBinding->ref();

    pLineColor = new SoMaterial;
    pLineColor->ref();
    LineColor.touch();

    // read the correct shape color from the preferences
    Base::Reference<ParameterGrp> hGrp =
        Gui::WindowParameter::getDefaultParameter()->GetGroup("Mod/Mesh");

    // Mesh color
    App::Color color = ShapeColor.getValue();
    unsigned long current = color.getPackedValue();
    unsigned long setting = hGrp->GetUnsigned("MeshColor", current);
    if (current != setting) {
        color.setPackedValue((uint32_t)setting);
        ShapeColor.setValue(color);
    }
    Transparency.setValue(hGrp->GetInt("MeshTransparency", 0));

    // Line color
    color = LineColor.getValue();
    current = color.getPackedValue();
    setting = hGrp->GetUnsigned("LineColor", current);
    if (current != setting) {
        color.setPackedValue((uint32_t)setting);
        LineColor.setValue(color);
    }
    LineTransparency.setValue(hGrp->GetInt("LineTransparency", 0));

    bool twoside = hGrp->GetBool("TwoSideRendering", false);
    if (twoside) {
        Lighting.setValue(1);
    }
    else {
        Lighting.setValue((long)0);
    }

    bool normal_per_vertex = hGrp->GetBool("VertexPerNormals", false);
    if (normal_per_vertex) {
        double angle = hGrp->GetFloat("CreaseAngle", 0.0);
        CreaseAngle.setValue(angle);
    }

    if (hGrp->GetBool("ShowBoundingBox", false)) {
        SelectionStyle.setValue(1);
    }

    Coloring.setStatus(App::Property::Hidden, true);
    // NOLINTEND
}

ViewProviderMesh::~ViewProviderMesh()
{
    pcHighlight->unref();
    pcShapeGroup->unref();
    pOpenColor->unref();
    pcLineStyle->unref();
    pcPointStyle->unref();
    pShapeHints->unref();
    pcMatBinding->unref();
    pLineColor->unref();
}

void ViewProviderMesh::onChanged(const App::Property* prop)
{
    // we're going to change the number of colors to one
    if (prop == &ShapeColor || prop == &ShapeMaterial) {
        pcMatBinding->value = SoMaterialBinding::OVERALL;
    }
    if (prop == &LineTransparency) {
        float trans = LineTransparency.getValue() / 100.0F;
        pLineColor->transparency = trans;
    }
    else if (prop == &LineWidth) {
        pcLineStyle->lineWidth = LineWidth.getValue();
    }
    else if (prop == &PointSize) {
        pcPointStyle->pointSize = PointSize.getValue();
    }
    else if (prop == &CreaseAngle) {
        pShapeHints->creaseAngle = Base::toRadians<float>(CreaseAngle.getValue());
    }
    else if (prop == &OpenEdges) {
        showOpenEdges(OpenEdges.getValue());
    }
    else if (prop == &Lighting) {
        if (Lighting.getValue() == 0) {
            pShapeHints->vertexOrdering = SoShapeHints::UNKNOWN_ORDERING;
        }
        else {
            pShapeHints->vertexOrdering = SoShapeHints::COUNTERCLOCKWISE;
        }
    }
    else if (prop == &LineColor) {
        const App::Color& c = LineColor.getValue();
        pLineColor->diffuseColor.setValue(c.r, c.g, c.b);
    }
    else if (prop == &Coloring) {
        tryColorPerVertexOrFace(Coloring.getValue());
    }
    else if (prop == &SelectionStyle) {
        pcHighlight->style =
            SelectionStyle.getValue() ? Gui::SoFCSelection::BOX : Gui::SoFCSelection::EMISSIVE;
    }
    else {
        // Set the inverse color for open edges
        if (prop == &ShapeColor) {
            setOpenEdgeColorFrom(ShapeColor.getValue());
        }
        else if (prop == &ShapeMaterial) {
            setOpenEdgeColorFrom(ShapeMaterial.getValue().diffuseColor);
        }
    }

    ViewProviderGeometryObject::onChanged(prop);
}

void ViewProviderMesh::setOpenEdgeColorFrom(const App::Color& c)
{
    float r = 1.0F - c.r;
    r = r < 0.5F ? 0.0F : 1.0F;
    float g = 1.0F - c.g;
    g = g < 0.5F ? 0.0F : 1.0F;
    float b = 1.0F - c.b;
    b = b < 0.5F ? 0.0F : 1.0F;
    pOpenColor->rgb.setValue(r, g, b);
}

SoShape* ViewProviderMesh::getShapeNode() const
{
    return nullptr;
}

SoNode* ViewProviderMesh::getCoordNode() const
{
    return nullptr;
}

/**
 * Extracts the mesh data from the feature \a pcFeature and creates
 * an Inventor node \a SoNode with these data.
 */
void ViewProviderMesh::attach(App::DocumentObject* pcFeat)
{
    ViewProviderGeometryObject::attach(pcFeat);

    pcHighlight->objectName = pcFeat->getNameInDocument();
    pcHighlight->documentName = pcFeat->getDocument()->getName();
    pcHighlight->subElementName = "Main";

    // Note: Since for mesh data the SoFCSelection node has no SoSeparator but
    // an SoGroup as parent the EMISSIVE style if set has fundamentally no effect.
    // This behaviour is given due to the fact that SoFCSelection inherits from
    // SoGroup (formerly SoSeparator). If we wanted to enable emissive overlay for
    // highlighting or selection we would need an SoSeparator as parent node below.

    // faces
    SoGroup* pcFlatRoot = new SoGroup();
    pcFlatRoot->addChild(pShapeHints);
    pcFlatRoot->addChild(pcShapeMaterial);
    pcFlatRoot->addChild(pcMatBinding);
    pcFlatRoot->addChild(pcHighlight);
    addDisplayMaskMode(pcFlatRoot, "Shaded");

    // points
    SoGroup* pcPointRoot = new SoGroup();
    pcPointRoot->addChild(pcPointStyle);
    pcPointRoot->addChild(pShapeHints);
    pcPointRoot->addChild(pcShapeMaterial);
    pcPointRoot->addChild(pcMatBinding);
    pcPointRoot->addChild(pcHighlight);
    addDisplayMaskMode(pcPointRoot, "Point");

    // wires
    SoLightModel* pcLightModel = new SoLightModel();
    pcLightModel->model = SoLightModel::BASE_COLOR;
    SoGroup* pcWireRoot = new SoGroup();
    pcWireRoot->addChild(pcLineStyle);
    pcWireRoot->addChild(pcLightModel);
    SoMaterialBinding* binding = new SoMaterialBinding;
    binding->value = SoMaterialBinding::OVERALL;  // doesn't set several colors
    pcWireRoot->addChild(binding);
    pcWireRoot->addChild(pLineColor);
    pcWireRoot->addChild(pcHighlight);
    addDisplayMaskMode(pcWireRoot, "Wireframe");

    // faces+wires
    // Avoid any Z-buffer artifacts, so that the lines always
    // appear on top of the faces
    SoPolygonOffset* offset = new SoPolygonOffset();
    offset->styles = SoPolygonOffset::FILLED;
    offset->factor = 1.0F;
    offset->units = 1.0F;

    SoSeparator* pcWireSep = new SoSeparator();
    pcWireSep->addChild(pcLineStyle);
    pcWireSep->addChild(pcLightModel);
    pcWireSep->addChild(binding);
    pcWireSep->addChild(pLineColor);
    pcWireSep->addChild(pcHighlight);

    SoGroup* pcFlatWireRoot = new SoGroup();
    pcFlatWireRoot->addChild(pcWireSep);
    pcFlatWireRoot->addChild(offset);
    pcFlatWireRoot->addChild(pShapeHints);
    pcFlatWireRoot->addChild(pcShapeMaterial);
    pcFlatWireRoot->addChild(pcMatBinding);
    pcFlatWireRoot->addChild(pcShapeGroup);
    addDisplayMaskMode(pcFlatWireRoot, "Flat Lines");

    if (getColorProperty() || getMaterialProperty()) {
        Coloring.setStatus(App::Property::Hidden, false);
    }
}

void ViewProviderMesh::updateData(const App::Property* prop)
{
    Gui::ViewProviderGeometryObject::updateData(prop);

    if (prop->is<App::PropertyColorList>()) {
        Coloring.setStatus(App::Property::Hidden, false);
    }
    else if (prop->is<Mesh::PropertyMaterial>()) {
        Coloring.setStatus(App::Property::Hidden, false);
    }
}

QIcon ViewProviderMesh::getIcon() const
{
    static QIcon icon = Gui::BitmapFactory().pixmap("Mesh_Tree");
    return icon;
}

App::PropertyColorList* ViewProviderMesh::getColorProperty() const
{
    if (pcObject) {
        std::map<std::string, App::Property*> Map;
        pcObject->getPropertyMap(Map);
        for (const auto& it : Map) {
            Base::Type type = it.second->getTypeId();
            if (type == App::PropertyColorList::getClassTypeId()) {
                App::PropertyColorList* colors = static_cast<App::PropertyColorList*>(it.second);
                return colors;
            }
        }
    }
    return nullptr;  // no such property found
}

void ViewProviderMesh::tryColorPerVertexOrFace(bool on)
{
    if (on) {
        const Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
        const Mesh::MeshObject& mesh = meshProp.getValue();
        int numPoints = static_cast<int>(mesh.countPoints());
        int numFacets = static_cast<int>(mesh.countFacets());

        if (App::PropertyColorList* colors = getColorProperty()) {
            if (colors->getSize() == numPoints) {
                setColorPerVertex(colors);
            }
            else if (colors->getSize() == numFacets) {
                setColorPerFace(colors);
            }
        }
        else if (Mesh::PropertyMaterial* material = getMaterialProperty()) {
            auto bind = material->getBinding();
            if (bind == MeshCore::MeshIO::Binding::OVERALL) {
                pcMatBinding->value = SoMaterialBinding::OVERALL;

                if (!material->getDiffuseColor().empty()) {
                    auto c = material->getDiffuseColor()[0];
                    pcShapeMaterial->diffuseColor.setValue(c.r, c.g, c.b);
                }
                if (!material->getTransparency().empty()) {
                    pcShapeMaterial->transparency.setValue(material->getTransparency()[0]);
                }
            }
            else if (bind == MeshCore::MeshIO::Binding::PER_VERTEX) {
                if (material->getDiffuseColor().size() == std::size_t(numPoints)) {
                    pcMatBinding->value = SoMaterialBinding::PER_VERTEX_INDEXED;
                    setDiffuseColor(material->getDiffuseColor());
                }
            }
            else if (bind == MeshCore::MeshIO::Binding::PER_FACE) {
                if (material->getAmbientColor().size() == std::size_t(numFacets)) {
                    pcMatBinding->value = SoMaterialBinding::PER_FACE;
                    setAmbientColor(material->getAmbientColor());
                }
                if (material->getDiffuseColor().size() == std::size_t(numFacets)) {
                    pcMatBinding->value = SoMaterialBinding::PER_FACE;
                    setDiffuseColor(material->getDiffuseColor());
                }
                if (material->getEmissiveColor().size() == std::size_t(numFacets)) {
                    pcMatBinding->value = SoMaterialBinding::PER_FACE;
                    setEmissiveColor(material->getEmissiveColor());
                }
                if (material->getSpecularColor().size() == std::size_t(numFacets)) {
                    pcMatBinding->value = SoMaterialBinding::PER_FACE;
                    setSpecularColor(material->getSpecularColor());
                }
                if (material->getTransparency().size() == std::size_t(numFacets)) {
                    pcMatBinding->value = SoMaterialBinding::PER_FACE;
                    setFacetTransparency(material->getTransparency());
                }
            }
        }
    }
    else {
        pcMatBinding->value = SoMaterialBinding::OVERALL;
        const App::Color& c = ShapeColor.getValue();
        pcShapeMaterial->diffuseColor.setValue(c.r, c.g, c.b);
        pcShapeMaterial->transparency.setValue(Transparency.getValue() / 100.0f);
    }
}

void ViewProviderMesh::setColorPerVertex(const App::PropertyColorList* prop)
{
    pcMatBinding->value = SoMaterialBinding::PER_VERTEX_INDEXED;
    setDiffuseColor(prop->getValues());
}

void ViewProviderMesh::setColorPerFace(const App::PropertyColorList* prop)
{
    pcMatBinding->value = SoMaterialBinding::PER_FACE;
    setDiffuseColor(prop->getValues());
}

void ViewProviderMesh::setColorField(const std::vector<App::Color>& val, SoMFColor& field)
{
    field.setNum(val.size());
    SbColor* col = field.startEditing();

    std::size_t i = 0;
    for (auto it : val) {
        col[i++].setValue(it.r, it.g, it.b);
    }

    field.finishEditing();
}

void ViewProviderMesh::setAmbientColor(const std::vector<App::Color>& val)
{
    setColorField(val, pcShapeMaterial->ambientColor);
}

void ViewProviderMesh::setDiffuseColor(const std::vector<App::Color>& val)
{
    setColorField(val, pcShapeMaterial->diffuseColor);
}

void ViewProviderMesh::setSpecularColor(const std::vector<App::Color>& val)
{
    setColorField(val, pcShapeMaterial->specularColor);
}

void ViewProviderMesh::setEmissiveColor(const std::vector<App::Color>& val)
{
    setColorField(val, pcShapeMaterial->emissiveColor);
}

Mesh::PropertyMaterial* ViewProviderMesh::getMaterialProperty() const
{
    if (pcObject) {
        std::map<std::string, App::Property*> Map;
        pcObject->getPropertyMap(Map);
        for (const auto& it : Map) {
            Base::Type type = it.second->getTypeId();
            if (type == Mesh::PropertyMaterial::getClassTypeId()) {
                Mesh::PropertyMaterial* material = static_cast<Mesh::PropertyMaterial*>(it.second);
                return material;
            }
        }
    }

    return nullptr;  // no such property found
}

void ViewProviderMesh::setDisplayMode(const char* ModeName)
{
    if (strcmp("Shaded", ModeName) == 0) {
        setDisplayMaskMode("Shaded");
    }
    else if (strcmp("Points", ModeName) == 0) {
        setDisplayMaskMode("Point");
    }
    else if (strcmp("Flat Lines", ModeName) == 0) {
        setDisplayMaskMode("Flat Lines");
    }
    else if (strcmp("Wireframe", ModeName) == 0) {
        setDisplayMaskMode("Wireframe");
    }

    ViewProviderGeometryObject::setDisplayMode(ModeName);
}

std::vector<std::string> ViewProviderMesh::getDisplayModes() const
{
    std::vector<std::string> StrList;

    // add your own modes
    StrList.emplace_back("Shaded");
    StrList.emplace_back("Wireframe");
    StrList.emplace_back("Flat Lines");
    StrList.emplace_back("Points");

    return StrList;
}

bool ViewProviderMesh::exportToVrml(const char* filename,
                                    const MeshCore::Material& mat,
                                    bool binary) const
{
    SoCoordinate3* coords = new SoCoordinate3();
    SoIndexedFaceSet* faces = new SoIndexedFaceSet();
    ViewProviderMeshBuilder builder;
    builder.createMesh(&static_cast<Mesh::Feature*>(pcObject)->Mesh, coords, faces);

    SoMaterialBinding* binding = new SoMaterialBinding;
    SoMaterial* material = new SoMaterial;

    if (static_cast<int>(mat.diffuseColor.size()) == coords->point.getNum()) {
        binding->value = SoMaterialBinding::PER_VERTEX_INDEXED;
    }
    else if (static_cast<int>(mat.diffuseColor.size()) == faces->coordIndex.getNum() / 4) {
        binding->value = SoMaterialBinding::PER_FACE_INDEXED;
    }

    if (mat.diffuseColor.size() > 1) {
        material->diffuseColor.setNum(mat.diffuseColor.size());
        SbColor* colors = material->diffuseColor.startEditing();
        for (unsigned int i = 0; i < mat.diffuseColor.size(); i++) {
            colors[i].setValue(mat.diffuseColor[i].r, mat.diffuseColor[i].g, mat.diffuseColor[i].b);
        }
        material->diffuseColor.finishEditing();
    }

    SoGroup* group = new SoGroup();
    group->addChild(material);
    group->addChild(binding);
    group->addChild(new SoTransform());
    group->addChild(coords);
    group->addChild(faces);

    SoToVRML2Action tovrml2;
    group->ref();
    tovrml2.apply(group);
    group->unref();
    SoVRMLGroup* vrmlRoot = tovrml2.getVRML2SceneGraph();
    vrmlRoot->ref();
    std::string buffer = Gui::SoFCDB::writeNodesToString(vrmlRoot);
    vrmlRoot->unref();  // release the memory as soon as possible

    Base::FileInfo fi(filename);
    if (binary) {
        Base::ofstream str(fi, std::ios::out | std::ios::binary);
        zipios::GZIPOutputStream gzip(str);
        if (gzip) {
            gzip << buffer;
            gzip.close();
            return true;
        }
    }
    else {
        Base::ofstream str(fi, std::ios::out);
        if (str) {
            str << buffer;
            str.close();
            return true;
        }
    }

    return false;
}

void ViewProviderMesh::exportMesh(const char* filename, const char* fmt) const
{
    MeshCore::MeshIO::Format format = MeshCore::MeshIO::Undefined;
    if (fmt) {
        std::string dummy = "meshfile.";
        dummy += fmt;
        format = MeshCore::MeshOutput::GetFormat(dummy.c_str());
    }

    MeshCore::Material mat;
    int numColors = pcShapeMaterial->diffuseColor.getNum();
    const SbColor* colors = pcShapeMaterial->diffuseColor.getValues(0);
    mat.diffuseColor.reserve(numColors);
    for (int i = 0; i < numColors; i++) {
        const SbColor& c = colors[i];
        mat.diffuseColor.emplace_back(c[0], c[1], c[2]);
    }

    Mesh::MeshObject mesh = static_cast<Mesh::Feature*>(getObject())->Mesh.getValue();
    mesh.setPlacement(static_cast<Mesh::Feature*>(getObject())->globalPlacement());
    if (mat.diffuseColor.size() == mesh.countPoints()) {
        mat.binding = MeshCore::MeshIO::PER_VERTEX;
    }
    else if (mat.diffuseColor.size() == mesh.countFacets()) {
        mat.binding = MeshCore::MeshIO::PER_FACE;
    }
    else {
        mat.binding = MeshCore::MeshIO::OVERALL;
    }

    mesh.save(filename, format, &mat, getObject()->Label.getValue());
}

void ViewProviderMesh::setupContextMenu(QMenu* menu, QObject* receiver, const char* member)
{
    ViewProviderGeometryObject::setupContextMenu(menu, receiver, member);

    // toggle command to display components
    Gui::ActionFunction* func = new Gui::ActionFunction(menu);
    QAction* act = menu->addAction(QObject::tr("Display components"));
    act->setCheckable(true);
    act->setChecked(pcMatBinding->value.getValue() == SoMaterialBinding::PER_FACE
                    && highlightMode == HighlighMode::Component);
    func->toggle(act, [this](bool on) {
        this->setHighlightedComponents(on);
    });

    QAction* seg = menu->addAction(QObject::tr("Display segments"));
    seg->setCheckable(true);
    seg->setChecked(pcMatBinding->value.getValue() == SoMaterialBinding::PER_FACE
                    && highlightMode == HighlighMode::Segment);
    func->toggle(seg, [this](bool on) {
        this->setHighlightedSegments(on);
    });

    QAction* col = menu->addAction(QObject::tr("Display colors"));
    col->setVisible(canHighlightColors());
    col->setCheckable(true);
    col->setChecked(highlightMode == HighlighMode::Color);
    func->toggle(col, [this](bool on) {
        this->setHighlightedColors(on);
    });
}

bool ViewProviderMesh::setEdit(int ModNum)
{
    if (ModNum == ViewProvider::Transform) {
        return ViewProviderGeometryObject::setEdit(ModNum);
    }
    else if (ModNum == ViewProvider::Color) {
        highlightComponents();
    }
    return true;
}

void ViewProviderMesh::unsetEdit(int ModNum)
{
    if (ModNum == ViewProvider::Transform) {
        ViewProviderGeometryObject::unsetEdit(ModNum);
    }
    else if (ModNum == ViewProvider::Color) {
        unhighlightSelection();
    }
}

bool ViewProviderMesh::createToolMesh(const std::vector<SbVec2f>& rclPoly,
                                      const SbViewVolume& vol,
                                      const Base::Vector3f& rcNormal,
                                      std::vector<MeshCore::MeshGeomFacet>& aFaces)
{
    float fX {}, fY {}, fZ {};
    SbVec3f pt1, pt2, pt3, pt4;
    MeshGeomFacet face;
    std::vector<Base::Vector3f> top, bottom, polygon;

    for (std::vector<SbVec2f>::const_iterator it = rclPoly.begin(); it != rclPoly.end(); ++it) {
        // the following element
        std::vector<SbVec2f>::const_iterator nt = it + 1;
        if (nt == rclPoly.end()) {
            nt = rclPoly.begin();
        }
        else if (*it == *nt) {
            continue;  // two adjacent vertices are equal
        }

        vol.projectPointToLine(*it, pt1, pt2);
        vol.projectPointToLine(*nt, pt3, pt4);

        // 1st facet
        pt1.getValue(fX, fY, fZ);
        face._aclPoints[0].Set(fX, fY, fZ);
        pt4.getValue(fX, fY, fZ);
        face._aclPoints[1].Set(fX, fY, fZ);
        pt3.getValue(fX, fY, fZ);
        face._aclPoints[2].Set(fX, fY, fZ);
        if (face.Area() > 0) {
            aFaces.push_back(face);
        }

        // 2nd facet
        pt1.getValue(fX, fY, fZ);
        face._aclPoints[0].Set(fX, fY, fZ);
        pt2.getValue(fX, fY, fZ);
        face._aclPoints[1].Set(fX, fY, fZ);
        pt4.getValue(fX, fY, fZ);
        face._aclPoints[2].Set(fX, fY, fZ);
        if (face.Area() > 0) {
            aFaces.push_back(face);
        }

        if (it + 1 < rclPoly.end()) {
            pt1.getValue(fX, fY, fZ);
            top.emplace_back(fX, fY, fZ);
            pt2.getValue(fX, fY, fZ);
            bottom.emplace_back(fX, fY, fZ);
            // polygon we need to triangulate (in x,y-plane)
            it->getValue(fX, fY);
            polygon.emplace_back(fX, fY, 0.0f);
        }
    }

    // now create the lids
    std::vector<MeshGeomFacet> aLid;
    MeshCore::EarClippingTriangulator cTria;
    cTria.SetPolygon(polygon);
    bool ok = cTria.TriangulatePolygon();

    std::vector<MeshFacet> faces = cTria.GetFacets();
    for (const auto& face : faces) {
        MeshGeomFacet topFacet;
        topFacet._aclPoints[0] = top[face._aulPoints[0]];
        topFacet._aclPoints[1] = top[face._aulPoints[1]];
        topFacet._aclPoints[2] = top[face._aulPoints[2]];
        if (topFacet.GetNormal() * rcNormal < 0) {
            std::swap(topFacet._aclPoints[1], topFacet._aclPoints[2]);
            topFacet.CalcNormal();
        }
        aFaces.push_back(topFacet);

        MeshGeomFacet botFacet;
        botFacet._aclPoints[0] = bottom[face._aulPoints[0]];
        botFacet._aclPoints[1] = bottom[face._aulPoints[1]];
        botFacet._aclPoints[2] = bottom[face._aulPoints[2]];
        if (botFacet.GetNormal() * rcNormal > 0) {
            std::swap(botFacet._aclPoints[1], botFacet._aclPoints[2]);
            botFacet.CalcNormal();
        }
        aFaces.push_back(botFacet);
    }

    return ok;
}

void ViewProviderMesh::showOpenEdges(bool show)
{
    (void)show;
}

namespace MeshGui
{
class MeshSplit
{
public:
    MeshSplit(ViewProviderMesh* mesh,
              std::vector<SbVec2f> poly,
              const Gui::ViewVolumeProjection& proj)
        : mesh(mesh)
        , poly(std::move(poly))
        , proj(proj)
    {}
    void cutMesh()
    {
        Gui::Document* gui = mesh->getDocument();
        gui->openCommand(QT_TRANSLATE_NOOP("Command", "Cut"));
        ViewProviderMesh* copy = makeCopy();
        mesh->cutMesh(poly, proj, false);
        copy->cutMesh(poly, proj, true);
        gui->commitCommand();
        delete this;
    }
    void trimMesh()
    {
        Gui::Document* gui = mesh->getDocument();
        gui->openCommand(QT_TRANSLATE_NOOP("Command", "Trim"));
        ViewProviderMesh* copy = makeCopy();
        mesh->trimMesh(poly, proj, false);
        copy->trimMesh(poly, proj, true);
        gui->commitCommand();
        delete this;
    }
    ViewProviderMesh* makeCopy() const
    {
        Gui::Document* gui = mesh->getDocument();
        App::Document* doc = gui->getDocument();

        Mesh::Feature* cpy = static_cast<Mesh::Feature*>(doc->addObject("Mesh::Feature"));
        Mesh::Feature* org = static_cast<Mesh::Feature*>(mesh->getObject());
        cpy->Label.setValue(org->Label.getValue());
        cpy->Mesh.setValue(org->Mesh.getValue());

        return static_cast<ViewProviderMesh*>(gui->getViewProvider(cpy));
    }

private:
    ViewProviderMesh* mesh;
    std::vector<SbVec2f> poly;
    Gui::ViewVolumeProjection proj;
};
}  // namespace MeshGui

void ViewProviderMesh::clipMeshCallback(void* ud, SoEventCallback* n)
{
    // show the wait cursor because this could take quite some time
    Gui::WaitCursor wc;

    // When this callback function is invoked we must in either case leave the edit mode
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(n->getUserData());
    view->setEditing(false);
    view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), clipMeshCallback, ud);
    n->setHandled();

    Gui::SelectionRole role {};
    std::vector<SbVec2f> clPoly = view->getGLPolygon(&role);
    if (clPoly.size() < 3) {
        return;
    }
    if (clPoly.front() != clPoly.back()) {
        clPoly.push_back(clPoly.front());
    }

    std::vector<Gui::ViewProvider*> views =
        view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
    if (!views.empty()) {
        Gui::Application::Instance->activeDocument()->openCommand(
            QT_TRANSLATE_NOOP("Command", "Cut"));
        bool commitCommand = false;
        for (auto it : views) {
            ViewProviderMesh* self = static_cast<ViewProviderMesh*>(it);
            if (self->getEditingMode() > -1) {
                self->finishEditing();
                SoCamera* cam = view->getSoRenderManager()->getCamera();
                SbViewVolume vv = cam->getViewVolume();
                Gui::ViewVolumeProjection proj(vv);
                proj.setTransform(static_cast<Mesh::Feature*>(self->getObject())
                                      ->Placement.getValue()
                                      .toMatrix());
                if (role == Gui::SelectionRole::Inner) {
                    self->cutMesh(clPoly, proj, true);
                    commitCommand = true;
                }
                else if (role == Gui::SelectionRole::Outer) {
                    self->cutMesh(clPoly, proj, false);
                    commitCommand = true;
                }
                else if (role == Gui::SelectionRole::Split) {
                    // We must delay the split because it adds a new
                    // node to the scenegraph which cannot be done while
                    // traversing it
                    Gui::TimerFunction* func = new Gui::TimerFunction();
                    func->setAutoDelete(true);
                    MeshSplit* split = new MeshSplit(self, clPoly, proj);
                    func->setFunction([split]() {
                        split->cutMesh();
                    });
                    func->singleShot(0);
                }
            }
        }

        if (commitCommand) {
            Gui::Application::Instance->activeDocument()->commitCommand();
        }
        else {
            Gui::Application::Instance->activeDocument()->abortCommand();
        }

        view->redraw();
    }
}

void ViewProviderMesh::trimMeshCallback(void* ud, SoEventCallback* n)
{
    // show the wait cursor because this could take quite some time
    Gui::WaitCursor wc;

    // When this callback function is invoked we must in either case leave the edit mode
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(n->getUserData());
    view->setEditing(false);
    view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), trimMeshCallback, ud);
    n->setHandled();

    Gui::SelectionRole role {};
    std::vector<SbVec2f> clPoly = view->getGLPolygon(&role);
    if (clPoly.size() < 3) {
        return;
    }
    if (clPoly.front() != clPoly.back()) {
        clPoly.push_back(clPoly.front());
    }

    std::vector<Gui::ViewProvider*> views =
        view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
    if (!views.empty()) {
        Gui::Application::Instance->activeDocument()->openCommand(
            QT_TRANSLATE_NOOP("Command", "Trim"));
        bool commitCommand = false;
        for (auto it : views) {
            ViewProviderMesh* self = static_cast<ViewProviderMesh*>(it);
            if (self->getEditingMode() > -1) {
                self->finishEditing();
                SoCamera* cam = view->getSoRenderManager()->getCamera();
                SbViewVolume vv = cam->getViewVolume();
                Gui::ViewVolumeProjection proj(vv);
                proj.setTransform(static_cast<Mesh::Feature*>(self->getObject())
                                      ->Placement.getValue()
                                      .toMatrix());
                if (role == Gui::SelectionRole::Inner) {
                    self->trimMesh(clPoly, proj, true);
                    commitCommand = true;
                }
                else if (role == Gui::SelectionRole::Outer) {
                    self->trimMesh(clPoly, proj, false);
                    commitCommand = true;
                }
                else if (role == Gui::SelectionRole::Split) {
                    // We must delay the split because it adds a new
                    // node to the scenegraph which cannot be done while
                    // traversing it
                    Gui::TimerFunction* func = new Gui::TimerFunction();
                    func->setAutoDelete(true);
                    MeshSplit* split = new MeshSplit(self, clPoly, proj);
                    func->setFunction([split]() {
                        split->trimMesh();
                    });
                    func->singleShot(0);
                }
            }
        }

        if (commitCommand) {
            Gui::Application::Instance->activeDocument()->commitCommand();
        }
        else {
            Gui::Application::Instance->activeDocument()->abortCommand();
        }

        view->redraw();
    }
}

void ViewProviderMesh::partMeshCallback(void* ud, SoEventCallback* cb)
{
    // show the wait cursor because this could take quite some time
    Gui::WaitCursor wc;

    // When this callback function is invoked we must in either case leave the edit mode
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(cb->getUserData());
    view->setEditing(false);
    view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), partMeshCallback, ud);
    cb->setHandled();

    Gui::SelectionRole role {};
    std::vector<SbVec2f> clPoly = view->getGLPolygon(&role);
    if (clPoly.size() < 3) {
        return;
    }
    if (clPoly.front() != clPoly.back()) {
        clPoly.push_back(clPoly.front());
    }

    // get the normal of the front clipping plane
    SbVec3f b, n;
    view->getNearPlane(b, n);
    Base::Vector3f cNormal(n[0], n[1], n[2]);
    SoCamera* pCam = view->getSoRenderManager()->getCamera();
    SbViewVolume vol = pCam->getViewVolume();

    // create a tool shape from these points
    std::vector<MeshCore::MeshGeomFacet> aFaces;
    if (!ViewProviderMesh::createToolMesh(clPoly, vol, cNormal, aFaces)) {
        Base::Console().Message("The picked polygon seems to have self-overlappings. This could "
                                "lead to strange results.");
    }

    MeshCore::MeshKernel toolMesh;
    bool locked = Base::Sequencer().setLocked(true);
    toolMesh = aFaces;
    Base::Sequencer().setLocked(locked);

    // Open a transaction object for the undo/redo stuff
    Gui::Application::Instance->activeDocument()->openCommand(
        QT_TRANSLATE_NOOP("Command", "Split"));

    try {
        std::vector<Gui::ViewProvider*> views =
            view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
        for (auto view : views) {
            ViewProviderMesh* that = static_cast<ViewProviderMesh*>(view);
            if (that->getEditingMode() > -1) {
                that->finishEditing();
                Base::Placement plm =
                    static_cast<Mesh::Feature*>(that->getObject())->Placement.getValue();
                plm.invert();
                MeshCore::MeshKernel copyToolMesh(toolMesh);
                copyToolMesh.Transform(plm.toMatrix());
                if (role == Gui::SelectionRole::Inner) {
                    that->splitMesh(copyToolMesh, cNormal, true);
                }
                else {
                    that->splitMesh(copyToolMesh, cNormal, false);
                }
            }
        }
    }
    catch (...) {
        // Don't rethrow any exception
    }

    // Close the transaction
    Gui::Application::Instance->activeDocument()->commitCommand();
    view->redraw();
}

void ViewProviderMesh::segmMeshCallback(void* ud, SoEventCallback* cb)
{
    // show the wait cursor because this could take quite some time
    Gui::WaitCursor wc;

    // When this callback function is invoked we must in either case leave the edit mode
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(cb->getUserData());
    view->setEditing(false);
    view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), segmMeshCallback, ud);
    cb->setHandled();

    Gui::SelectionRole role {};
    std::vector<SbVec2f> clPoly = view->getGLPolygon(&role);
    if (clPoly.size() < 3) {
        return;
    }
    if (clPoly.front() != clPoly.back()) {
        clPoly.push_back(clPoly.front());
    }

    // get the normal of the front clipping plane
    SbVec3f b, n;
    view->getNearPlane(b, n);
    Base::Vector3f cNormal(n[0], n[1], n[2]);
    SoCamera* pCam = view->getSoRenderManager()->getCamera();
    SbViewVolume vol = pCam->getViewVolume();

    // create a tool shape from these points
    std::vector<MeshCore::MeshGeomFacet> aFaces;
    if (!ViewProviderMesh::createToolMesh(clPoly, vol, cNormal, aFaces)) {
        Base::Console().Message("The picked polygon seems to have self-overlappings. This could "
                                "lead to strange results.");
    }

    MeshCore::MeshKernel toolMesh;
    bool locked = Base::Sequencer().setLocked(true);
    toolMesh = aFaces;
    Base::Sequencer().setLocked(locked);

    // Open a transaction object for the undo/redo stuff
    Gui::Application::Instance->activeDocument()->openCommand(
        QT_TRANSLATE_NOOP("Command", "Segment"));

    try {
        std::vector<Gui::ViewProvider*> views =
            view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
        for (auto view : views) {
            ViewProviderMesh* that = static_cast<ViewProviderMesh*>(view);
            if (that->getEditingMode() > -1) {
                that->finishEditing();
                Base::Placement plm =
                    static_cast<Mesh::Feature*>(that->getObject())->Placement.getValue();
                plm.invert();
                MeshCore::MeshKernel copyToolMesh(toolMesh);
                copyToolMesh.Transform(plm.toMatrix());
                if (role == Gui::SelectionRole::Inner) {
                    that->segmentMesh(copyToolMesh, cNormal, true);
                }
                else {
                    that->segmentMesh(copyToolMesh, cNormal, false);
                }
            }
        }
    }
    catch (...) {
        // Don't rethrow any exception
    }

    // Close the transaction
    Gui::Application::Instance->activeDocument()->commitCommand();
    view->redraw();
}

void ViewProviderMesh::selectGLCallback(void* ud, SoEventCallback* n)
{
    // When this callback function is invoked we must in either case leave the edit mode
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(n->getUserData());
    view->setEditing(false);
    view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), selectGLCallback, ud);
    n->setHandled();

    std::vector<SbVec2f> clPoly = view->getGLPolygon();
    if (clPoly.size() != 2) {
        return;
    }
    const SoEvent* ev = n->getEvent();

    SbVec2f pos = clPoly[0];
    float pX {}, pY {};
    pos.getValue(pX, pY);
    const SbVec2s& sz = view->getSoRenderManager()->getViewportRegion().getViewportSizePixels();
    float fRatio = view->getSoRenderManager()->getViewportRegion().getViewportAspectRatio();
    if (fRatio > 1.0F) {
        pX = (pX - 0.5F) / fRatio + 0.5F;
        pos.setValue(pX, pY);
    }
    else if (fRatio < 1.0F) {
        pY = (pY - 0.5F) * fRatio + 0.5F;
        pos.setValue(pX, pY);
    }

    short x1 = (short)(pX * sz[0] + 0.5F);
    short y1 = (short)(pY * sz[1] + 0.5F);
    SbVec2s loc = ev->getPosition();
    short x2 = loc[0];
    short y2 = loc[1];

    short x = (x1 + x2) / 2;
    short y = (y1 + y2) / 2;
    short w = (x2 - x1);
    short h = (y2 - y1);
    if (w < 0) {
        w = -w;
    }
    if (h < 0) {
        h = -h;
    }

    std::vector<Gui::ViewProvider*> views;
    views = view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
    for (auto it : views) {
        ViewProviderMesh* that = static_cast<ViewProviderMesh*>(it);
        if (that->getEditingMode() > -1) {
            that->finishEditing();
            that->selectArea(x,
                             y,
                             w,
                             h,
                             view->getSoRenderManager()->getViewportRegion(),
                             view->getSoRenderManager()->getCamera());
        }
    }

    view->redraw();
}

void ViewProviderMesh::getFacetsFromPolygon(const std::vector<SbVec2f>& picked,
                                            const Base::ViewProjMethod& proj,
                                            SbBool inner,
                                            std::vector<Mesh::FacetIndex>& indices) const
{
    const bool ok = true;
    Base::Polygon2d polygon;
    for (auto it : picked) {
        polygon.Add(Base::Vector2d(it[0], it[1]));
    }

    // Get the attached mesh property
    Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    MeshCore::MeshAlgorithm cAlg(meshProp.getValue().getKernel());
    cAlg.CheckFacets(&proj, polygon, true, indices);

    if (!inner) {
        // get the indices that are completely outside
        std::vector<Mesh::FacetIndex> complete(meshProp.getValue().countFacets());
        std::generate(complete.begin(), complete.end(), Base::iotaGen<Mesh::FacetIndex>(0));
        std::sort(indices.begin(), indices.end());
        std::vector<Mesh::FacetIndex> complementary;
        std::back_insert_iterator<std::vector<Mesh::FacetIndex>> biit(complementary);
        std::set_difference(complete.begin(), complete.end(), indices.begin(), indices.end(), biit);
        indices = complementary;
    }

    if (!ok) {  // note: the mouse grabbing needs to be released
        Base::Console().Message("The picked polygon seems to have self-overlappings. This could "
                                "lead to strange results.");
    }
}

std::vector<Mesh::FacetIndex> ViewProviderMesh::getFacetsOfRegion(const SbViewportRegion& select,
                                                                  const SbViewportRegion& region,
                                                                  SoCamera* camera) const
{
    SoSeparator* root = new SoSeparator();
    root->ref();
    root->addChild(camera);
    root->addChild(this->getCoordNode());
    root->addChild(this->getShapeNode());
    Gui::SoGLSelectAction gl(region, select);
    gl.apply(root);
    root->unref();

    std::vector<Mesh::FacetIndex> faces;
    faces.insert(faces.end(), gl.indices.begin(), gl.indices.end());
    return faces;
}

void ViewProviderMesh::panCamera(SoCamera* cam,
                                 float aspectratio,
                                 const SbPlane& panplane,
                                 const SbVec2f& currpos,
                                 const SbVec2f& prevpos)
{
    if (!cam) {  // can happen for empty scenegraph
        return;
    }
    if (currpos == prevpos) {  // useless invocation
        return;
    }


    // Find projection points for the last and current mouse coordinates.
    SbViewVolume vv = cam->getViewVolume(aspectratio);
    SbLine line;
    vv.projectPointToLine(currpos, line);
    SbVec3f current_planept;
    panplane.intersect(line, current_planept);
    vv.projectPointToLine(prevpos, line);
    SbVec3f old_planept;
    panplane.intersect(line, old_planept);

    // Reposition camera according to the vector difference between the
    // projected points.
    cam->position = cam->position.getValue() - (current_planept - old_planept);
}

void ViewProviderMesh::boxZoom(const SbBox2s& box, const SbViewportRegion& vp, SoCamera* cam)
{
    SbViewVolume vv = cam->getViewVolume(vp.getViewportAspectRatio());

    short sizeX {}, sizeY {};
    box.getSize(sizeX, sizeY);
    SbVec2s size = vp.getViewportSizePixels();

    // The bbox must not be empty i.e. width and length is zero, but it is possible that
    // either width or length is zero
    if (sizeX == 0 && sizeY == 0) {
        return;
    }

    // Get the new center in normalized pixel coordinates
    short xmin {};
    short xmax {};
    short ymin {};
    short ymax {};
    box.getBounds(xmin, ymin, xmax, ymax);
    const SbVec2f center((float)((xmin + xmax) / 2) / (float)std::max((int)(size[0] - 1), 1),
                         (float)(size[1] - (ymin + ymax) / 2)
                             / (float)std::max((int)(size[1] - 1), 1));

    SbPlane plane = vv.getPlane(cam->focalDistance.getValue());
    panCamera(cam, vp.getViewportAspectRatio(), plane, SbVec2f(0.5, 0.5), center);

    // Set height or height angle of the camera
    float scaleX = (float)sizeX / (float)size[0];
    float scaleY = (float)sizeY / (float)size[1];
    float scale = std::max<float>(scaleX, scaleY);
    if (cam->getTypeId() == SoOrthographicCamera::getClassTypeId()) {
        float height = static_cast<SoOrthographicCamera*>(cam)->height.getValue() * scale;
        static_cast<SoOrthographicCamera*>(cam)->height = height;
    }
    else if (cam->getTypeId() == SoPerspectiveCamera::getClassTypeId()) {
        float height = static_cast<SoPerspectiveCamera*>(cam)->heightAngle.getValue() / 2.0F;
        height = 2.0F * atan(tan(height) * scale);
        static_cast<SoPerspectiveCamera*>(cam)->heightAngle = height;
    }
}

std::vector<Mesh::FacetIndex>
ViewProviderMesh::getVisibleFacetsAfterZoom(const SbBox2s& rect,
                                            const SbViewportRegion& vp,
                                            SoCamera* camera) const
{
    // camera copy will be deleted inside getVisibleFacets()
    // because the ref counter reaches 0
    camera = static_cast<SoCamera*>(camera->copy());
    boxZoom(rect, vp, camera);
    return getVisibleFacets(vp, camera);
}

void ViewProviderMesh::renderGLCallback(void* ud, SoAction* action)
{
    if (action->isOfType(SoGLRenderAction::getClassTypeId())) {
        ViewProviderMesh* mesh = static_cast<ViewProviderMesh*>(ud);
        Gui::SoVisibleFaceAction fa;
        fa.apply(mesh->getRoot());
    }
}

namespace MeshGui
{

class Vertex
{
public:
    Vertex(const MeshCore::MeshKernel& kernel,
           const MeshCore::MeshFacetGrid& grid,
           const Base::Vector3f& pos)
        : kernel(kernel)
        , grid(grid)
        , pos(pos)
    {}
    bool visible(const Base::Vector3f& base) const
    {
        MeshCore::MeshAlgorithm meshAlg(kernel);
        bool ok = meshAlg.IsVertexVisible(base, pos, grid);
        return ok;
    }

private:
    const MeshCore::MeshKernel& kernel;
    const MeshCore::MeshFacetGrid& grid;
    Base::Vector3f pos;
};

}  // namespace MeshGui

std::vector<Mesh::FacetIndex> ViewProviderMesh::getVisibleFacets(const SbViewportRegion& vp,
                                                                 SoCamera* camera) const
{
    const Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    const Mesh::MeshObject& mesh = meshProp.getValue();
    uint32_t count = (uint32_t)mesh.countFacets();

    SoSeparator* root = new SoSeparator;
    root->ref();
    root->addChild(camera);

    SoLightModel* lm = new SoLightModel();
    lm->model = SoLightModel::BASE_COLOR;
    root->addChild(lm);
    SoMaterial* mat = new SoMaterial();
    mat->diffuseColor.setNum(count);
    SbColor* diffcol = mat->diffuseColor.startEditing();
    for (uint32_t i = 0; i < count; i++) {
        float t {};
        diffcol[i].setPackedValue(i << 8, t);
    }

    mat->diffuseColor.finishEditing();

    SoMaterialBinding* bind = new SoMaterialBinding();
    bind->value = SoMaterialBinding::PER_FACE;

    root->addChild(mat);
    root->addChild(bind);
    root->addChild(this->getCoordNode());
    root->addChild(this->getShapeNode());

    // Coin3d's off-screen renderer doesn't work out-of-the-box any more on most recent Linux
    // systems. So, use FreeCAD's offscreen renderer now.
    Gui::SoQtOffscreenRenderer renderer(vp);
    renderer.setBackgroundColor(SbColor4f(0.0F, 0.0F, 0.0F));

    QImage img;
    renderer.render(root);
    renderer.writeToImage(img);
    root->unref();

    int width = img.width();
    int height = img.height();
    QRgb color = 0;
    std::vector<Mesh::FacetIndex> faces;
    for (int y = 0; y < height; y++) {
        for (int x = 0; x < width; x++) {
            QRgb rgb = img.pixel(x, y);
            rgb = rgb - (0xff << 24);
            if (rgb != 0 && rgb != color) {
                color = rgb;
                faces.push_back((Mesh::FacetIndex)rgb);
            }
        }
    }

    std::sort(faces.begin(), faces.end());
    faces.erase(std::unique(faces.begin(), faces.end()), faces.end());

    return faces;
}

void ViewProviderMesh::cutMesh(const std::vector<SbVec2f>& picked,
                               const Base::ViewProjMethod& proj,
                               SbBool inner)
{
    // Get the facet indices inside the tool mesh
    std::vector<Mesh::FacetIndex> indices;
    getFacetsFromPolygon(picked, proj, inner, indices);
    removeFacets(indices);
}

void ViewProviderMesh::trimMesh(const std::vector<SbVec2f>& polygon,
                                const Base::ViewProjMethod& proj,
                                SbBool inner)
{
    Mesh::MeshObject* mesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.startEditing();

    Base::Polygon2d polygon2d;
    for (auto it : polygon) {
        polygon2d.Add(Base::Vector2d(it[0], it[1]));
    }

    Mesh::MeshObject::CutType type = inner ? Mesh::MeshObject::INNER : Mesh::MeshObject::OUTER;
    mesh->trim(polygon2d, proj, type);
    static_cast<Mesh::Feature*>(pcObject)->Mesh.finishEditing();
    pcObject->purgeTouched();
}

void ViewProviderMesh::splitMesh(const MeshCore::MeshKernel& toolMesh,
                                 const Base::Vector3f& normal,
                                 SbBool clip_inner)
{
    // Get the attached mesh property
    Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    const MeshCore::MeshKernel& meshPropKernel = meshProp.getValue().getKernel();

    // Get the facet indices inside the tool mesh
    std::vector<Mesh::FacetIndex> indices;
    MeshCore::MeshFacetGrid cGrid(meshPropKernel);
    MeshCore::MeshAlgorithm cAlg(meshPropKernel);
    cAlg.GetFacetsFromToolMesh(toolMesh, normal, cGrid, indices);
    if (!clip_inner) {
        // get the indices that are completely outside
        std::vector<Mesh::FacetIndex> complete(meshPropKernel.CountFacets());
        std::generate(complete.begin(), complete.end(), Base::iotaGen<Mesh::FacetIndex>(0));
        std::sort(indices.begin(), indices.end());
        std::vector<Mesh::FacetIndex> complementary;
        std::back_insert_iterator<std::vector<Mesh::FacetIndex>> biit(complementary);
        std::set_difference(complete.begin(), complete.end(), indices.begin(), indices.end(), biit);
        indices = complementary;
    }

    // Remove the facets from the mesh and create a new one
    Mesh::MeshObject* kernel = meshProp.getValue().meshFromSegment(indices);
    removeFacets(indices);
    Mesh::Feature* splitMesh = static_cast<Mesh::Feature*>(
        App::GetApplication().getActiveDocument()->addObject("Mesh::Feature",
                                                             pcObject->getNameInDocument()));
    // Note: deletes also kernel
    splitMesh->Mesh.setValuePtr(kernel);
    static_cast<Mesh::Feature*>(pcObject)->purgeTouched();
}

void ViewProviderMesh::segmentMesh(const MeshCore::MeshKernel& toolMesh,
                                   const Base::Vector3f& normal,
                                   SbBool clip_inner)
{
    // Get the attached mesh property
    Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    const MeshCore::MeshKernel& meshPropKernel = meshProp.getValue().getKernel();

    // Get the facet indices inside the tool mesh
    std::vector<Mesh::FacetIndex> indices;
    MeshCore::MeshFacetGrid cGrid(meshPropKernel);
    MeshCore::MeshAlgorithm cAlg(meshPropKernel);
    cAlg.GetFacetsFromToolMesh(toolMesh, normal, cGrid, indices);
    if (!clip_inner) {
        // get the indices that are completely outside
        std::vector<Mesh::FacetIndex> complete(meshPropKernel.CountFacets());
        std::generate(complete.begin(), complete.end(), Base::iotaGen<Mesh::FacetIndex>(0));
        std::sort(indices.begin(), indices.end());
        std::vector<Mesh::FacetIndex> complementary;
        std::back_insert_iterator<std::vector<Mesh::FacetIndex>> biit(complementary);
        std::set_difference(complete.begin(), complete.end(), indices.begin(), indices.end(), biit);
        indices = complementary;
    }

    Mesh::MeshObject* kernel = meshProp.startEditing();
    kernel->addSegment(indices);
    meshProp.finishEditing();
    static_cast<Mesh::Feature*>(pcObject)->purgeTouched();
}

void ViewProviderMesh::faceInfoCallback(void* ud, SoEventCallback* n)
{
    const SoMouseButtonEvent* mbe = static_cast<const SoMouseButtonEvent*>(n->getEvent());
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(n->getUserData());

    // Mark all incoming mouse button events as handled, especially, to deactivate the selection
    // node
    n->getAction()->setHandled();
    if (mbe->getButton() == SoMouseButtonEvent::BUTTON2 && mbe->getState() == SoButtonEvent::UP) {
        n->setHandled();
        // context-menu
        QMenu menu;
        QAction* cl = menu.addAction(QObject::tr("Leave info mode"));
        QAction* id = menu.exec(QCursor::pos());
        if (cl == id) {
            view->setEditing(false);
            view->getWidget()->setCursor(QCursor(Qt::ArrowCursor));
            view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), faceInfoCallback, ud);
            std::list<Gui::GLGraphicsItem*> glItems =
                view->getGraphicsItemsOfType(Gui::GLFlagWindow::getClassTypeId());
            for (auto glItem : glItems) {
                view->removeGraphicsItem(glItem);
                delete glItem;
            }

            // See comment below
            ParameterGrp::handle hGrp = App::GetApplication().GetParameterGroupByPath(
                "User parameter:BaseApp/Preferences/View");
            hGrp->SetBool("ShowNaviCube", hGrp->GetBool("ShowNaviCube", true));
        }
    }
    else if (mbe->getButton() == SoMouseButtonEvent::BUTTON1
             && mbe->getState() == SoButtonEvent::DOWN) {
        const SoPickedPoint* point = n->getPickedPoint();
        if (!point) {
            Base::Console().Message("No facet picked.\n");
            return;
        }

        n->setHandled();

        // By specifying the indexed mesh node 'pcFaceSet' we make sure that the picked point is
        // really from the mesh we render and not from any other geometry
        Gui::ViewProvider* vp = view->getViewProviderByPathFromTail(point->getPath());
        if (!vp || !vp->isDerivedFrom<ViewProviderMesh>()) {
            return;
        }

        // FIXME: The Flag class doesn't work well (flickering) when the NaviCube is enabled.
        // To avoid this the NaviCube is disabled for the time the flags are shown.
        // When leaving this mode the NaviCube can be displayed again.
        // For a proper solution it's best to move the Flag class to the QGraphicsView API.
        view->setEnabledNaviCube(false);

        ViewProviderMesh* that = static_cast<ViewProviderMesh*>(vp);
        const SoDetail* detail = point->getDetail(that->getShapeNode());
        if (detail && detail->getTypeId() == SoFaceDetail::getClassTypeId()) {
            // get the boundary to the picked facet
            const SoFaceDetail* faceDetail = static_cast<const SoFaceDetail*>(detail);
            Mesh::FacetIndex uFacet = faceDetail->getFaceIndex();
            that->faceInfo(uFacet);
            Gui::GLFlagWindow* flags = nullptr;
            std::list<Gui::GLGraphicsItem*> glItems =
                view->getGraphicsItemsOfType(Gui::GLFlagWindow::getClassTypeId());
            if (glItems.empty()) {
                flags = new Gui::GLFlagWindow(view);
                view->addGraphicsItem(flags);
            }
            else {
                flags = static_cast<Gui::GLFlagWindow*>(glItems.front());
            }

            int point1 =
                static_cast<const SoPointDetail*>(faceDetail->getPoint(0))->getCoordinateIndex();
            int point2 =
                static_cast<const SoPointDetail*>(faceDetail->getPoint(1))->getCoordinateIndex();
            int point3 =
                static_cast<const SoPointDetail*>(faceDetail->getPoint(2))->getCoordinateIndex();
            Gui::Flag* flag = new Gui::Flag;
            flag->setText(QObject::tr("Index: %1").arg(uFacet));
            QString toolTip = QString::fromLatin1("Facet index: %1\n"
                                                  "Points: <%2, %3, %4>")
                                  .arg(uFacet)
                                  .arg(point1)
                                  .arg(point2)
                                  .arg(point3);
            flag->setToolTip(toolTip);
            flag->setOrigin(point->getPoint());
            flags->addFlag(flag, Gui::FlagLayout::TopRight);
        }
    }
}

void ViewProviderMesh::fillHoleCallback(void* ud, SoEventCallback* n)
{
    const SoMouseButtonEvent* mbe = static_cast<const SoMouseButtonEvent*>(n->getEvent());
    Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(n->getUserData());

    // Mark all incoming mouse button events as handled, especially, to deactivate the selection
    // node
    n->getAction()->setHandled();
    if (mbe->getButton() == SoMouseButtonEvent::BUTTON2 && mbe->getState() == SoButtonEvent::UP) {
        n->setHandled();
        // context-menu
        QMenu menu;
        QAction* cl = menu.addAction(QObject::tr("Leave hole-filling mode"));
        QAction* id = menu.exec(QCursor::pos());
        if (cl == id) {
            view->setEditing(false);
            view->setSelectionEnabled(true);
            view->getWidget()->setCursor(QCursor(Qt::ArrowCursor));
            view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(), fillHoleCallback, ud);
        }
    }
    else if (mbe->getButton() == SoMouseButtonEvent::BUTTON1
             && mbe->getState() == SoButtonEvent::DOWN) {
        const SoPickedPoint* point = n->getPickedPoint();
        if (!point) {
            Base::Console().Message("No facet picked.\n");
            return;
        }

        n->setHandled();

        // By specifying the indexed mesh node 'pcFaceSet' we make sure that the picked point is
        // really from the mesh we render and not from any other geometry
        Gui::ViewProvider* vp = view->getViewProviderByPathFromTail(point->getPath());
        if (!vp || !vp->isDerivedFrom<ViewProviderMesh>()) {
            return;
        }
        ViewProviderMesh* that = static_cast<ViewProviderMesh*>(vp);
        const SoDetail* detail = point->getDetail(that->getShapeNode());
        if (detail && detail->getTypeId() == SoFaceDetail::getClassTypeId()) {
            // get the boundary to the picked facet
            Mesh::FacetIndex uFacet = ((SoFaceDetail*)detail)->getFaceIndex();
            that->fillHole(uFacet);
        }
    }
}

void ViewProviderMesh::markPartCallback(void* ud, SoEventCallback* n)
{
    // handle only mouse button events
    if (n->getEvent()->isOfType(SoMouseButtonEvent::getClassTypeId())) {
        const SoMouseButtonEvent* mbe = static_cast<const SoMouseButtonEvent*>(n->getEvent());
        Gui::View3DInventorViewer* view = static_cast<Gui::View3DInventorViewer*>(n->getUserData());

        // Mark all incoming mouse button events as handled, especially, to deactivate the selection
        // node
        n->getAction()->setHandled();
        if (mbe->getButton() == SoMouseButtonEvent::BUTTON2
            && mbe->getState() == SoButtonEvent::UP) {
            n->setHandled();
            // context-menu
            QMenu menu;
            QAction* cl = menu.addAction(QObject::tr("Leave removal mode"));
            QAction* rm = menu.addAction(QObject::tr("Delete selected faces"));
            QAction* cf = menu.addAction(QObject::tr("Clear selected faces"));
            QAction* id = menu.exec(QCursor::pos());
            if (cl == id) {
                view->setEditing(false);
                view->setSelectionEnabled(true);
                view->removeEventCallback(SoMouseButtonEvent::getClassTypeId(),
                                          markPartCallback,
                                          ud);

                std::vector<ViewProvider*> views =
                    view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
                for (auto view : views) {
                    static_cast<ViewProviderMesh*>(view)->clearSelection();
                }
            }
            else if (cf == id) {
                std::vector<ViewProvider*> views =
                    view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
                for (auto view : views) {
                    static_cast<ViewProviderMesh*>(view)->clearSelection();
                }
            }
            else if (rm == id) {
                Gui::Application::Instance->activeDocument()->openCommand(
                    QT_TRANSLATE_NOOP("Command", "Delete"));
                std::vector<ViewProvider*> views =
                    view->getViewProvidersOfType(ViewProviderMesh::getClassTypeId());
                for (auto view : views) {
                    static_cast<ViewProviderMesh*>(view)->deleteSelection();
                }
                view->redraw();
                Gui::Application::Instance->activeDocument()->commitCommand();
            }
        }
        else if (mbe->getButton() == SoMouseButtonEvent::BUTTON1
                 && mbe->getState() == SoButtonEvent::DOWN) {
            const SoPickedPoint* point = n->getPickedPoint();
            if (!point) {
                Base::Console().Message("No facet picked.\n");
                return;
            }

            n->setHandled();

            // By specifying the indexed mesh node 'pcFaceSet' we make sure that the picked point is
            // really from the mesh we render and not from any other geometry
            Gui::ViewProvider* vp = view->getViewProviderByPathFromTail(point->getPath());
            if (!vp || !vp->isDerivedFrom<ViewProviderMesh>()) {
                return;
            }
            ViewProviderMesh* that = static_cast<ViewProviderMesh*>(vp);
            const SoDetail* detail = point->getDetail(that->getShapeNode());
            if (detail && detail->getTypeId() == SoFaceDetail::getClassTypeId()) {
                // get the boundary to the picked facet
                Mesh::FacetIndex uFacet = static_cast<const SoFaceDetail*>(detail)->getFaceIndex();
                that->selectComponent(uFacet);
            }
        }
    }
}

void ViewProviderMesh::faceInfo(Mesh::FacetIndex uFacet)
{
    Mesh::Feature* fea = static_cast<Mesh::Feature*>(this->getObject());
    const MeshCore::MeshKernel& rKernel = fea->Mesh.getValue().getKernel();
    const MeshCore::MeshFacetArray& facets = rKernel.GetFacets();
    if (uFacet < facets.size()) {
        MeshCore::MeshFacet face = facets[uFacet];
        MeshCore::MeshGeomFacet tria = rKernel.GetFacet(face);
        Base::Console().Message(
            "Mesh: %s Facet %lu: Points: <%lu, %lu, %lu>, Neighbours: <%lu, %lu, %lu>\n"
            "Triangle: <[%.6f, %.6f, %.6f], [%.6f, %.6f, %.6f], [%.6f, %.6f, %.6f]>\n",
            fea->getNameInDocument(),
            uFacet,
            face._aulPoints[0],
            face._aulPoints[1],
            face._aulPoints[2],
            face._aulNeighbours[0],
            face._aulNeighbours[1],
            face._aulNeighbours[2],
            tria._aclPoints[0].x,
            tria._aclPoints[0].y,
            tria._aclPoints[0].z,
            tria._aclPoints[1].x,
            tria._aclPoints[1].y,
            tria._aclPoints[1].z,
            tria._aclPoints[2].x,
            tria._aclPoints[2].y,
            tria._aclPoints[2].z);
    }
}

void ViewProviderMesh::fillHole(Mesh::FacetIndex uFacet)
{
    // get parameter from user settings
    Base::Reference<ParameterGrp> hGrp =
        Gui::WindowParameter::getDefaultParameter()->GetGroup("Mod/Mesh");
    int level = (int)hGrp->GetInt("FillHoleLevel", 2);

    // get the boundary to the picked facet
    std::list<Mesh::PointIndex> aBorder;
    Mesh::Feature* fea = static_cast<Mesh::Feature*>(this->getObject());
    const MeshCore::MeshKernel& rKernel = fea->Mesh.getValue().getKernel();
    MeshCore::MeshRefPointToFacets cPt2Fac(rKernel);
    MeshCore::MeshAlgorithm meshAlg(rKernel);
    meshAlg.GetFacetBorder(uFacet, aBorder);
    std::vector<Mesh::PointIndex> boundary(aBorder.begin(), aBorder.end());
    std::list<std::vector<Mesh::PointIndex>> boundaries;
    boundaries.push_back(boundary);
    meshAlg.SplitBoundaryLoops(boundaries);

    std::vector<MeshCore::MeshFacet> newFacets;
    std::vector<Base::Vector3f> newPoints;
    unsigned long numberOfOldPoints = rKernel.CountPoints();
    for (const auto& it : boundaries) {
        if (it.size() < 3 /* || it->size() > 200*/) {
            continue;
        }
        boundary = it;
        MeshCore::MeshFacetArray faces;
        MeshCore::MeshPointArray points;
        MeshCore::QuasiDelaunayTriangulator cTria /*(0.05f)*/;
        cTria.SetVerifier(new MeshCore::TriangulationVerifierV2);
        if (meshAlg.FillupHole(boundary, cTria, faces, points, level, &cPt2Fac)) {
            if (boundary.front() == boundary.back()) {
                boundary.pop_back();
            }
            // the triangulation may produce additional points which we must take into account when
            // appending to the mesh
            unsigned long countBoundaryPoints = boundary.size();
            unsigned long countDifference = points.size() - countBoundaryPoints;
            if (countDifference > 0) {
                MeshCore::MeshPointArray::_TIterator pt = points.begin() + countBoundaryPoints;
                for (unsigned long i = 0; i < countDifference; i++, pt++) {
                    boundary.push_back(numberOfOldPoints++);
                    newPoints.push_back(*pt);
                }
            }
            for (auto& face : faces) {
                face._aulPoints[0] = boundary[face._aulPoints[0]];
                face._aulPoints[1] = boundary[face._aulPoints[1]];
                face._aulPoints[2] = boundary[face._aulPoints[2]];
                newFacets.push_back(face);
            }
        }
    }

    if (newFacets.empty()) {
        return;  // nothing to do
    }

    // add the facets to the mesh and open a transaction object for the undo/redo stuff
    Gui::Application::Instance->activeDocument()->openCommand(
        QT_TRANSLATE_NOOP("Command", "Fill hole"));
    Mesh::MeshObject* kernel = fea->Mesh.startEditing();
    kernel->addFacets(newFacets, newPoints, true);
    fea->Mesh.finishEditing();
    Gui::Application::Instance->activeDocument()->commitCommand();
}

void ViewProviderMesh::setFacetTransparency(const std::vector<float>& facetTransparency)
{
    if (pcShapeMaterial->diffuseColor.getNum() != int(facetTransparency.size())) {
        App::Color c = ShapeColor.getValue();
        pcShapeMaterial->diffuseColor.setNum(facetTransparency.size());
        SbColor* cols = pcShapeMaterial->diffuseColor.startEditing();
        for (std::size_t index = 0; index < facetTransparency.size(); ++index) {
            cols[index].setValue(c.r, c.g, c.b);
        }
        pcShapeMaterial->diffuseColor.finishEditing();
    }

    pcShapeMaterial->transparency.setNum(facetTransparency.size());
    float* tran = pcShapeMaterial->transparency.startEditing();
    for (std::size_t index = 0; index < facetTransparency.size(); ++index) {
        tran[index] = facetTransparency[index];
    }

    pcShapeMaterial->transparency.finishEditing();
    pcMatBinding->value = SoMaterialBinding::PER_FACE;
}

void ViewProviderMesh::resetFacetTransparency()
{
    pcMatBinding->value = SoMaterialBinding::OVERALL;
    App::Color c = ShapeColor.getValue();
    pcShapeMaterial->diffuseColor.setValue(c.r, c.g, c.b);
    pcShapeMaterial->transparency.setValue(0);
}

/*! The triangles with the passed indices are already added to the mesh. */
void ViewProviderMesh::appendFacets(const std::vector<Mesh::FacetIndex>&)
{}

void ViewProviderMesh::removeFacets(const std::vector<Mesh::FacetIndex>& facets)
{
    // Get the attached mesh property
    Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    Mesh::MeshObject* kernel = meshProp.startEditing();

    // get the colour property if there
    App::PropertyColorList* prop = getColorProperty();
    bool ok = Coloring.getValue();

    if (prop && prop->getSize() == static_cast<int>(kernel->countPoints())) {
        std::vector<Mesh::PointIndex> pointDegree;
        unsigned long invalid = kernel->getPointDegree(facets, pointDegree);
        if (invalid > 0) {
            // switch off coloring mode
            Coloring.setValue(false);

            const std::vector<App::Color>& colors = prop->getValues();
            std::vector<App::Color> valid_colors;
            valid_colors.reserve(kernel->countPoints() - invalid);
            std::size_t numPoints = pointDegree.size();
            for (std::size_t index = 0; index < numPoints; index++) {
                if (pointDegree[index] > 0) {
                    valid_colors.push_back(colors[index]);
                }
            }

            prop->setValues(valid_colors);
        }
    }
    else if (prop && prop->getSize() == static_cast<int>(kernel->countFacets())) {
        // switch off coloring mode
        Coloring.setValue(false);

        std::vector<bool> validFacets(kernel->countFacets(), true);
        for (auto it : facets) {
            validFacets[it] = false;
        }

        const std::vector<App::Color>& colors = prop->getValues();
        std::vector<App::Color> valid_colors;
        valid_colors.reserve(colors.size());
        std::size_t numColors = colors.size();
        for (std::size_t index = 0; index < numColors; index++) {
            if (validFacets[index]) {
                valid_colors.push_back(colors[index]);
            }
        }

        prop->setValues(valid_colors);
    }

    // Remove the facets from the mesh and open a transaction object for the undo/redo stuff
    kernel->deleteFacets(facets);
    meshProp.finishEditing();
    pcObject->purgeTouched();

    Coloring.setValue(ok);
}

void ViewProviderMesh::selectFacet(Mesh::FacetIndex facet)
{
    std::vector<Mesh::FacetIndex> selection;
    selection.push_back(facet);

    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.addFacetsToSelection(selection);

    // Colorize the selection
    pcMatBinding->value = SoMaterialBinding::PER_FACE;
    int uCtFacets = (int)rMesh.countFacets();

    if (uCtFacets != pcShapeMaterial->diffuseColor.getNum()) {
        highlightSelection();
    }
    else {
        pcShapeMaterial->diffuseColor.set1Value(facet, 1.0F, 0.0F, 0.0F);
    }
}

void ViewProviderMesh::deselectFacet(Mesh::FacetIndex facet)
{
    std::vector<Mesh::FacetIndex> selection;
    selection.push_back(facet);

    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.removeFacetsFromSelection(selection);

    // Colorize the selection
    pcMatBinding->value = SoMaterialBinding::PER_FACE;
    int uCtFacets = (int)rMesh.countFacets();

    if (rMesh.hasSelectedFacets()) {
        if (uCtFacets != pcShapeMaterial->diffuseColor.getNum()) {
            highlightSelection();
        }
        else {
            App::Color c = ShapeColor.getValue();
            pcShapeMaterial->diffuseColor.set1Value(facet, c.r, c.g, c.b);
        }
    }
    else {
        unhighlightSelection();
    }
}

bool ViewProviderMesh::isFacetSelected(Mesh::FacetIndex facet)
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    const MeshCore::MeshFacetArray& faces = rMesh.getKernel().GetFacets();
    return faces[facet].IsFlag(MeshCore::MeshFacet::SELECTED);
}

void ViewProviderMesh::selectComponent(Mesh::FacetIndex uFacet)
{
    std::vector<Mesh::FacetIndex> selection;
    selection.push_back(uFacet);

    MeshCore::MeshTopFacetVisitor clVisitor(selection);
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    const MeshCore::MeshKernel& rKernel = rMesh.getKernel();
    MeshCore::MeshAlgorithm(rKernel).ResetFacetFlag(MeshCore::MeshFacet::VISIT);
    rKernel.VisitNeighbourFacets(clVisitor, uFacet);
    rMesh.addFacetsToSelection(selection);

    // Colorize the selection
    highlightSelection();
}

void ViewProviderMesh::deselectComponent(Mesh::FacetIndex uFacet)
{
    std::vector<Mesh::FacetIndex> selection;
    selection.push_back(uFacet);

    MeshCore::MeshTopFacetVisitor clVisitor(selection);
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    const MeshCore::MeshKernel& rKernel = rMesh.getKernel();
    MeshCore::MeshAlgorithm(rKernel).ResetFacetFlag(MeshCore::MeshFacet::VISIT);
    rKernel.VisitNeighbourFacets(clVisitor, uFacet);
    rMesh.removeFacetsFromSelection(selection);

    // Colorize the selection
    if (rMesh.hasSelectedFacets()) {
        highlightSelection();
    }
    else {
        unhighlightSelection();
    }
}

void ViewProviderMesh::setSelection(const std::vector<Mesh::FacetIndex>& indices)
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.clearFacetSelection();
    rMesh.addFacetsToSelection(indices);

    // Colorize the selection
    if (indices.empty()) {
        unhighlightSelection();
    }
    else {
        highlightSelection();
    }
}

void ViewProviderMesh::addSelection(const std::vector<Mesh::FacetIndex>& indices)
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.addFacetsToSelection(indices);

    // Colorize the selection
    highlightSelection();
}

void ViewProviderMesh::removeSelection(const std::vector<Mesh::FacetIndex>& indices)
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.removeFacetsFromSelection(indices);

    // Colorize the selection
    if (rMesh.hasSelectedFacets()) {
        highlightSelection();
    }
    else {
        unhighlightSelection();
    }
}

void ViewProviderMesh::invertSelection()
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    const MeshCore::MeshFacetArray& faces = rMesh.getKernel().GetFacets();
    MeshCore::MeshIsNotFlag<MeshCore::MeshFacet> flag;
    unsigned long num_notsel =
        std::count_if(faces.begin(), faces.end(), [flag](const MeshCore::MeshFacet& f) {
            return flag(f, MeshCore::MeshFacet::SELECTED);
        });
    std::vector<Mesh::FacetIndex> notselect;
    notselect.reserve(num_notsel);
    MeshCore::MeshFacetArray::_TConstIterator beg = faces.begin();
    MeshCore::MeshFacetArray::_TConstIterator end = faces.end();
    for (MeshCore::MeshFacetArray::_TConstIterator jt = beg; jt != end; ++jt) {
        if (!jt->IsFlag(MeshCore::MeshFacet::SELECTED)) {
            notselect.push_back(jt - beg);
        }
    }
    setSelection(notselect);
}

void ViewProviderMesh::clearSelection()
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.clearFacetSelection();
    unhighlightSelection();
}

void ViewProviderMesh::deleteSelection()
{
    std::vector<Mesh::FacetIndex> indices;
    Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    const Mesh::MeshObject& rMesh = meshProp.getValue();
    rMesh.getFacetsFromSelection(indices);
    if (!indices.empty()) {
        rMesh.clearFacetSelection();
        unhighlightSelection();
        removeFacets(indices);
    }
}

bool ViewProviderMesh::hasSelection() const
{
    Mesh::PropertyMeshKernel& meshProp = static_cast<Mesh::Feature*>(pcObject)->Mesh;
    const Mesh::MeshObject& rMesh = meshProp.getValue();
    return rMesh.hasSelectedFacets();
}

void ViewProviderMesh::selectArea(short x,
                                  short y,
                                  short w,
                                  short h,
                                  const SbViewportRegion& region,
                                  SoCamera* camera)
{
    SbViewportRegion vp;
    vp.setViewportPixels(x, y, w, h);
    std::vector<Mesh::FacetIndex> faces = getFacetsOfRegion(vp, region, camera);

    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.addFacetsToSelection(faces);

    // Colorize the selected part
    highlightSelection();
}

void ViewProviderMesh::highlightSelection()
{
    std::vector<Mesh::FacetIndex> selection;
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    rMesh.getFacetsFromSelection(selection);
    if (selection.empty()) {
        // If no faces are selected then simply return even
        // without calling unhighlightSelection()
        return;
    }

    // Colorize the selection
    pcMatBinding->value = SoMaterialBinding::PER_FACE;
    App::Color c = ShapeColor.getValue();
    int uCtFacets = (int)rMesh.countFacets();
    pcShapeMaterial->diffuseColor.setNum(uCtFacets);

    SbColor* cols = pcShapeMaterial->diffuseColor.startEditing();
    for (int i = 0; i < uCtFacets; i++) {
        cols[i].setValue(c.r, c.g, c.b);
    }
    for (Mesh::FacetIndex it : selection) {
        cols[it].setValue(1.0F, 0.0F, 0.0F);
    }
    pcShapeMaterial->diffuseColor.finishEditing();
}

void ViewProviderMesh::unhighlightSelection()
{
    App::Color c = ShapeColor.getValue();
    pcMatBinding->value = SoMaterialBinding::OVERALL;
    pcShapeMaterial->diffuseColor.setNum(1);
    pcShapeMaterial->diffuseColor.setValue(c.r, c.g, c.b);
}

void ViewProviderMesh::setHighlightedComponents(bool on)
{
    if (on) {
        highlightMode = HighlighMode::Component;
        highlightComponents();
    }
    else {
        highlightMode = HighlighMode::None;
        unhighlightSelection();
    }
}

void ViewProviderMesh::highlightComponents()
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    std::vector<std::vector<Mesh::FacetIndex>> comps = rMesh.getComponents();

    // Colorize the components
    pcMatBinding->value = SoMaterialBinding::PER_FACE;
    int uCtFacets = (int)rMesh.countFacets();
    pcShapeMaterial->diffuseColor.setNum(uCtFacets);

    SbColor* cols = pcShapeMaterial->diffuseColor.startEditing();
    for (const auto& comp : comps) {
        float fMax = (float)RAND_MAX;
        float fRed = (float)rand() / fMax;
        float fGrn = (float)rand() / fMax;
        float fBlu = (float)rand() / fMax;
        for (Mesh::FacetIndex jt : comp) {
            cols[jt].setValue(fRed, fGrn, fBlu);
        }
    }
    pcShapeMaterial->diffuseColor.finishEditing();
}

void ViewProviderMesh::setHighlightedSegments(bool on)
{
    if (on) {
        highlightMode = HighlighMode::Segment;
        highlightSegments();
    }
    else {
        highlightMode = HighlighMode::None;
        unhighlightSelection();
    }
}

void ViewProviderMesh::highlightSegments()
{
    std::vector<App::Color> colors;
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    unsigned long numSegm = rMesh.countSegments();
    colors.resize(numSegm, this->ShapeColor.getValue());

    for (unsigned long i = 0; i < numSegm; i++) {
        App::Color col;
        if (col.fromHexString(rMesh.getSegment(i).getColor())) {
            colors[i] = col;
        }
    }

    highlightSegments(colors);
}

void ViewProviderMesh::highlightSegments(const std::vector<App::Color>& colors)
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    unsigned long numSegm = rMesh.countSegments();
    if (numSegm > 0 && numSegm == colors.size()) {
        // Colorize the components
        pcMatBinding->value = SoMaterialBinding::PER_FACE;
        int uCtFacets = (int)rMesh.countFacets();

        pcShapeMaterial->diffuseColor.setNum(uCtFacets);
        SbColor* cols = pcShapeMaterial->diffuseColor.startEditing();
        for (unsigned long i = 0; i < numSegm; i++) {
            std::vector<Mesh::FacetIndex> segm = rMesh.getSegment(i).getIndices();
            float fRed = colors[i].r;
            float fGrn = colors[i].g;
            float fBlu = colors[i].b;
            for (Mesh::FacetIndex it : segm) {
                cols[it].setValue(fRed, fGrn, fBlu);
            }
        }
        pcShapeMaterial->diffuseColor.finishEditing();
    }
    else if (colors.size() == 1) {
        pcMatBinding->value = SoMaterialBinding::OVERALL;
        float fRed = colors[0].r;
        float fGrn = colors[0].g;
        float fBlu = colors[0].b;
        pcShapeMaterial->diffuseColor.setValue(fRed, fGrn, fBlu);
    }
}

void ViewProviderMesh::setHighlightedColors(bool on)
{
    if (on) {
        highlightMode = HighlighMode::Color;
        highlightColors();
    }
    else {
        highlightMode = HighlighMode::None;
        unhighlightSelection();
    }
}

void ViewProviderMesh::highlightColors()
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    {
        App::PropertyColorList* prop = Base::freecad_dynamic_cast<App::PropertyColorList>(
            pcObject->getPropertyByName("FaceColors"));
        if (prop && prop->getSize() == int(rMesh.countFacets())) {
            setColorPerFace(prop);
        }
    }
    {
        App::PropertyColorList* prop = Base::freecad_dynamic_cast<App::PropertyColorList>(
            pcObject->getPropertyByName("VertexColors"));
        if (prop && prop->getSize() == int(rMesh.countPoints())) {
            setColorPerVertex(prop);
        }
    }
}

bool ViewProviderMesh::canHighlightColors() const
{
    const Mesh::MeshObject& rMesh = static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue();
    {
        App::PropertyColorList* prop = Base::freecad_dynamic_cast<App::PropertyColorList>(
            pcObject->getPropertyByName("FaceColors"));
        if (prop && prop->getSize() == int(rMesh.countFacets())) {
            return true;
        }
    }
    {
        App::PropertyColorList* prop = Base::freecad_dynamic_cast<App::PropertyColorList>(
            pcObject->getPropertyByName("VertexColors"));
        if (prop && prop->getSize() == int(rMesh.countPoints())) {
            return true;
        }
    }

    return false;
}

PyObject* ViewProviderMesh::getPyObject()
{
    if (!pyViewObject) {
        pyViewObject = new ViewProviderMeshPy(this);
    }
    pyViewObject->IncRef();
    return pyViewObject;
}

// ------------------------------------------------------

PROPERTY_SOURCE(MeshGui::ViewProviderIndexedFaceSet, MeshGui::ViewProviderMesh)

ViewProviderIndexedFaceSet::ViewProviderIndexedFaceSet()
{
    // NOLINTBEGIN
    pcMeshCoord = nullptr;
    pcMeshFaces = nullptr;
    // NOLINTEND
}

ViewProviderIndexedFaceSet::~ViewProviderIndexedFaceSet() = default;

/**
 * Extracts the mesh data from the feature \a pcFeature and creates
 * an Inventor node \a SoNode with these data.
 */
void ViewProviderIndexedFaceSet::attach(App::DocumentObject* pcFeat)
{
    ViewProviderMesh::attach(pcFeat);

    pcMeshCoord = new SoCoordinate3;
    pcHighlight->addChild(pcMeshCoord);

    pcMeshFaces = new SoFCIndexedFaceSet;
    pcHighlight->addChild(pcMeshFaces);

    // read the threshold from the preferences
    Base::Reference<ParameterGrp> hGrp =
        Gui::WindowParameter::getDefaultParameter()->GetGroup("Mod/Mesh");
    int size = hGrp->GetInt("RenderTriangleLimit", -1);
    if (size > 0) {
        static_cast<SoFCIndexedFaceSet*>(pcMeshFaces)->renderTriangleLimit =
            (unsigned int)(pow(10.0F, size));
    }
}

void ViewProviderIndexedFaceSet::updateData(const App::Property* prop)
{
    ViewProviderMesh::updateData(prop);
    if (prop->is<Mesh::PropertyMeshKernel>()) {
        ViewProviderMeshBuilder builder;
        builder.createMesh(prop, pcMeshCoord, pcMeshFaces);
        showOpenEdges(OpenEdges.getValue());
        highlightSelection();
    }
}

void ViewProviderIndexedFaceSet::showOpenEdges(bool show)
{
    if (pcOpenEdge) {
        // remove the node and destroy the data
        pcRoot->removeChild(pcOpenEdge);
        pcOpenEdge = nullptr;
    }

    if (show) {
        pcOpenEdge = new SoSeparator();
        pcOpenEdge->addChild(pcLineStyle);
        pcOpenEdge->addChild(pOpenColor);

        pcOpenEdge->addChild(pcMeshCoord);
        SoIndexedLineSet* lines = new SoIndexedLineSet;
        pcOpenEdge->addChild(lines);

        // add to the highlight node
        pcRoot->addChild(pcOpenEdge);

        // Build up the lines with indices to the list of vertices 'pcMeshCoord'
        int index = 0;
        const MeshCore::MeshKernel& rMesh =
            static_cast<Mesh::Feature*>(pcObject)->Mesh.getValue().getKernel();
        const MeshCore::MeshFacetArray& rFaces = rMesh.GetFacets();
        for (const auto& rFace : rFaces) {
            for (int i = 0; i < 3; i++) {
                if (rFace._aulNeighbours[i] == MeshCore::FACET_INDEX_MAX) {
                    lines->coordIndex.set1Value(index++, rFace._aulPoints[i]);
                    lines->coordIndex.set1Value(index++, rFace._aulPoints[(i + 1) % 3]);
                    lines->coordIndex.set1Value(index++, SO_END_LINE_INDEX);
                }
            }
        }
    }
}

SoShape* ViewProviderIndexedFaceSet::getShapeNode() const
{
    return this->pcMeshFaces;
}

SoNode* ViewProviderIndexedFaceSet::getCoordNode() const
{
    return this->pcMeshCoord;
}

// ------------------------------------------------------

PROPERTY_SOURCE(MeshGui::ViewProviderMeshObject, MeshGui::ViewProviderMesh)

ViewProviderMeshObject::ViewProviderMeshObject()
{
    // NOLINTBEGIN
    pcMeshNode = nullptr;
    pcMeshShape = nullptr;
    // NOLINTEND
}

ViewProviderMeshObject::~ViewProviderMeshObject() = default;

void ViewProviderMeshObject::attach(App::DocumentObject* pcFeat)
{
    ViewProviderMesh::attach(pcFeat);

    pcMeshNode = new SoFCMeshObjectNode;
    pcHighlight->addChild(pcMeshNode);

    pcMeshShape = new SoFCMeshObjectShape;
    pcHighlight->addChild(pcMeshShape);

    // read the threshold from the preferences
    Base::Reference<ParameterGrp> hGrp =
        Gui::WindowParameter::getDefaultParameter()->GetGroup("Mod/Mesh");
    int size = hGrp->GetInt("RenderTriangleLimit", -1);
    if (size > 0) {
        pcMeshShape->renderTriangleLimit = (unsigned int)(pow(10.0F, size));
    }
}

void ViewProviderMeshObject::updateData(const App::Property* prop)
{
    ViewProviderMesh::updateData(prop);
    if (prop->is<Mesh::PropertyMeshKernel>()) {
        const Mesh::PropertyMeshKernel* mesh = static_cast<const Mesh::PropertyMeshKernel*>(prop);
        this->pcMeshNode->mesh.setValue(
            Base::Reference<const Mesh::MeshObject>(mesh->getValuePtr()));
        // Needs to update internal bounding box caches
        this->pcMeshShape->touch();
    }
}

void ViewProviderMeshObject::showOpenEdges(bool show)
{
    if (pcOpenEdge) {
        // remove the node and destroy the data
        pcRoot->removeChild(pcOpenEdge);
        pcOpenEdge = nullptr;
    }

    if (show) {
        pcOpenEdge = new SoSeparator();
        pcOpenEdge->addChild(pcLineStyle);
        pcOpenEdge->addChild(pOpenColor);

        pcOpenEdge->addChild(pcMeshNode);
        pcOpenEdge->addChild(new SoFCMeshObjectBoundary);

        // add to the highlight node
        pcRoot->addChild(pcOpenEdge);
    }
}

SoShape* ViewProviderMeshObject::getShapeNode() const
{
    return this->pcMeshShape;
}

SoNode* ViewProviderMeshObject::getCoordNode() const
{
    return this->pcMeshNode;
}
